Negligible electronic contribution to heat transfer across intrinsic metal/graphene interfaces

TL;DR

This study investigates the electronic contribution to heat transfer across metal/graphene interfaces, finding it negligible in pristine conditions but significant when graphene is damaged, with phonons dominating heat conduction otherwise.

Contribution

It provides experimental evidence that electrons contribute minimally to heat transfer across intrinsic metal/graphene interfaces, highlighting the impact of interface damage on electronic heat conduction.

Findings

Thermal conductance of pristine Pd/graphene interfaces is about 42 MW/m^2K.

Damage to graphene during sputtering increases conductance to around 300 MW/m^2K.

Electronic heat conduction is negligible in undamaged interfaces, but significant when graphene is damaged.

Abstract

Despite the importance of high thermal conductance (i.e. low thermal resistance) of metal contacts to thermal management of graphene devices, prior reported thermal conductance of metal/graphene interfaces are all relatively low, only 20-40 MW m$^{-2}$ K$^{-1}$. One possible route to improve the thermal conductance ($G$) of metal/graphene interfaces is through additional heat conduction by electrons, since graphene can be easily doped by metals. In this paper, we evaluate the electronic heat conduction across metal/graphene interfaces by measuring the thermal conductance of Pd/transferred graphene (trG)/Pd interfaces, prepared by either thermal evaporation or radio-frequency (rf) magnetron sputtering, over a wide temperature range of 80 to 500 K. We find that for the samples prepared by thermal evaporation, the thermal conductance of Pd/trG/Pd is 42 MW m$^{-2}$ K$^{-1}$. The thermal conductance only weakly depends on temperature, which suggests that heat is predominantly carried by phonons across the intrinsic Pd/graphene interface. However, for Pd/trG/Pd samples with the top Pd films deposited by rf magnetron sputtering, we observe a significant increment of thermal conductance from the intrinsic value of 42 MW m$^{-2}$ K$^{-1}$ to 300 MW m$^{-2}$ K$^{-1}$, and $G$ is roughly proportional to $T$. We attribute the enhancement of thermal conductance to an additional channel of heat transport by electrons via atomic-scale pinholes formed in the graphene during the sputtering process. We thus conclude that electrons play a negligible role in heat conduction across intrinsic interfaces of metal and pristine graphene, and the contribution of electrons is only substantial if graphene is damaged.